Polymer nanocomposites based on two-dimensional nanomaterials

Bayan, Rajarshi; Karak, Niranjan

doi:10.1016/b978-0-12-817650-4.00008-5

Cited by 14 publications

(9 citation statements)

References 73 publications

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“…AFM is a high-resolution, scanning probe microscopic technique which can provide information about surface topology of the nanomaterial/nanocomposite and local properties like surface thickness, height, friction, or magnetism based on the interaction between the sharp tip of cantilever probe and the material surface. , In addition, it enables determination of the properties of adsorbed protein (elasticity, Young’s modulus, etc. ), and the effects of interaction between protein and nanosheet (protein folding and unfolding, agglomeration, etc.).…”

Section: Analytical Methods For Evaluation Of 2d Nanomaterial–protein...mentioning

confidence: 99%

Nanobio Interface Between Proteins and 2D Nanomaterials

Roy

Aastha

Deo

et al. 2023

ACS Appl. Mater. Interfaces

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nanomaterials have significantly contributed to recent advances in material sciences and nanotechnology, owing to their layered structure. Despite their potential as multifunctional theranostic agents, the biomedical translation of these materials is limited due to a lack of knowledge and control over their interaction with complex biological systems. In a biological microenvironment, the high surface energy of nanomaterials leads to diverse interactions with biological moieties such as proteins, which play a crucial role in unique physiological processes. These interactions can alter the size, surface charge, shape, and interfacial composition of the nanomaterial, ultimately affecting its biological activity and identity. This review critically discusses the possible interactions between proteins and 2D nanomaterials, along with a wide spectrum of analytical techniques that can be used to study and characterize such interplay. A better understanding of these interactions would help circumvent potential risks and provide guidance toward the safer design of 2D nanomaterials as a platform technology for various biomedical applications.

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Section: Analytical Methods For Evaluation Of 2d Nanomaterial–protein...mentioning

confidence: 99%

Nanobio Interface Between Proteins and 2D Nanomaterials

Roy

Aastha

Deo

et al. 2023

ACS Appl. Mater. Interfaces

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“…[ 120 ] Though it resembles graphene, containing residual oxygen and other heteroatoms with some structural defects degrade its electric properties. [ 121 ] While graphene derivatives (GO and rGO) can be produced in a huge quantity in their stable dispersions, [ 122 ] the major challenge for such materials is the ability to produce high‐quality graphene at a larger scale. [ 123 ] Hybridization of various carbonaceous compounds is also attractive due to their combined electrochemical properties, which provide enhanced capacitive performances of SC devices.…”

Section: Components Of Textile‐based Supercapacitorsmentioning

confidence: 99%

Smart Electronic Textile‐Based Wearable Supercapacitors

et al. 2022

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Electronic textiles (e-textiles) have drawn significant attention from the scientific and engineering community as lightweight and comfortable next-generation wearable devices due to their ability to interface with the human body, and continuously monitor, collect, and communicate various physiological parameters. However, one of the major challenges for the commercialization and further growth of e-textiles is the lack of compatible power supply units. Thin and flexible supercapacitors (SCs), among various energy storage systems, are gaining consideration due to their salient features including excellent lifetime, lightweight, and high-power density. Textile-based SCs are thus an exciting energy storage solution to power smart gadgets integrated into clothing. Here, materials, fabrications, and characterization strategies for textile-based SCs are reviewed. The recent progress of textile-based SCs is then summarized in terms of their electrochemical performances, followed by the discussion on key parameters for their wearable electronics applications, including washability, flexibility, and scalability. Finally, the perspectives on their research and technological prospects to facilitate an essential step towards moving from laboratory-based flexible and wearable SCs to industrial-scale mass production are presented. IntroductionWearable electronic textiles (e-textiles) have been going through significant evolutions in recent years, due to the continuous progress of material science and nanotechnology, miniaturization, and wireless revolution. [1,2] E-textiles possess functionalities such as sensing, computation, display, and communication, [3][4][5][6]

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“…Though resembles graphene, residual oxygen, and other heteroatoms with possible structural defects degrade its electric properties. [ 61 ] Graphene derivatives (GO and rGO) can be produced in large quantities in their stable dispersions, [ 62 ] however, the major challenge is the production of high‐quality graphene at a larger scale. [ 63 ] Hybridization of various carbonaceous compounds is also attractive in wearable electronics applications.…”

Section: Materials For Printed E‐textilesmentioning

confidence: 99%

Advances in Printed Electronic Textiles

Islam,

Afroj,

Yin

et al. 2023

Advanced Science

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Electronic textiles (e‐textiles) have emerged as a revolutionary solution for personalized healthcare, enabling the continuous collection and communication of diverse physiological parameters when seamlessly integrated with the human body. Among various methods employed to create wearable e‐textiles, printing offers unparalleled flexibility and comfort, seamlessly integrating wearables into garments. This has spurred growing research interest in printed e‐textiles, due to their vast design versatility, material options, fabrication techniques, and wide‐ranging applications. Here, a comprehensive overview of the crucial considerations in fabricating printed e‐textiles is provided, encompassing the selection of conductive materials and substrates, as well as the essential pre‐ and post‐treatments involved. Furthermore, the diverse printing techniques and the specific requirements are discussed, highlighting the advantages and limitations of each method. Additionally, the multitude of wearable applications made possible by printed e‐textiles is explored, such as their integration as various sensors, supercapacitors, and heated garments. Finally, a forward‐looking perspective is provided, discussing future prospects and emerging trends in the realm of printed wearable e‐textiles. As advancements in materials science, printing technologies, and design innovation continue to unfold, the transformative potential of printed e‐textiles in healthcare and beyond is poised to revolutionize the way wearable technology interacts and benefits.

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Polymer nanocomposites based on two-dimensional nanomaterials

Cited by 14 publications

References 73 publications

Nanobio Interface Between Proteins and 2D Nanomaterials

Nanobio Interface Between Proteins and 2D Nanomaterials

Smart Electronic Textile‐Based Wearable Supercapacitors

Advances in Printed Electronic Textiles

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